experimental and numerical studies on sloshing dynamics of
TRANSCRIPT
Research ArticleExperimental and Numerical Studies on Sloshing Dynamics ofPCS Water Tank of Nuclear Island Building
Xiaojun Li ,1,2 Chenning Song ,1 Guoliang Zhou,3 ChaoWei,3 andMing Lu4
1The College of Architecture and Civil Engineering, Beijing University of Technology, Beijing 100124, China2Institute of Geophysics, China Earthquake Administration, Beijing 100081, China3Nuclear and Radiation Safety Center, Ministry of Environmental Protection of the People’s Republic of China, Beijing 100082, China4Institute of Crustal Dynamics, China Earthquake Administration, Beijing 100085, China
Correspondence should be addressed to Chenning Song; [email protected]
Received 30 November 2017; Revised 25 March 2018; Accepted 4 April 2018; Published 20 May 2018
Academic Editor: Michel Giot
Copyright © 2018 Xiaojun Li et al. This is an open access article distributed under the Creative Commons Attribution License,which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
Water tank is one important component of passive containment cooling system (PCS) of nuclear island building. The sloshingfrequency of water is much less than structure frequency and large-amplitude sloshing occurs easily when subjected to seismicloadings.Therefore, the sloshing dynamics and fluid-structure interaction (FSI) effect of water tank should be considered when thedynamic response of nuclear island building is analyzed. A 1/16 scaled model was designed and the shaking table test was done, inwhich the hydrodynamic pressure time histories and attenuation data of wave height were recorded.Then the sloshing frequenciesand 1st sloshing damping ratio were recognized. Moreover, modal analysis and time history analysis of numerical model weredone by ADINA software. By comparing the sloshing frequencies and hydrodynamic pressures, it is proved that the test methodis reasonable and the formulation of potential-based fluid elements (PBFE) can be used to simulate FSI effect of nuclear islandbuilding.
1. Introduction
Passive containment cooling system (PCS) is the significantcharacteristic of the third-generation nuclear power plants[1], which is different from the traditional nuclear powerplants. It is known that the sloshing frequency of wateris far less than structure frequency, so the long periodcomponents of seismic loadings could not be ignored inthe analysis of water tank. Moreover, the influence of watertank on floor response spectra under seismic loadings shouldbe considered emphatically. The dynamic characteristics ofwater tank should be studied to analyze the seismic responseof nuclear island building accurately.
FSI effect is the key problem for dynamic analysis of watertank of nuclear island building. Related to the type of externalloads, shape of container, and depth of liquid, the motion offree fluid surface may be simple planar, nonplanar, breaking,and so on [2–4]. Focused on the nonlinear sloshing in arectangular tank, Faltinsen et al. [5, 6] studied the horizontal,
vertical, and pitching motion. Moreover, the stable andunstable frequency domains of the planar resonant standingwaves, the swirling waves, and the square-like resonantstanding waves were researched. In the research on FSI effectof nuclear power plants, Lo Frano and Forasassi [7–9] didsome research on liquid metal nuclear reactor consideringthe FSI effect subjected to seismic loads. Zhao et al. [10]used the Arbitrary Lagrange Eulerian (ALE) algorithm tosimulate the seismic response of AP1000 shield building andstudied the influence of water tank.The research showed thatwater tank could reduce the dynamic response of structure.Xu et al. [11] used the smoothed particle hydrodynamics(SPH) and finite element method (FEM) coupling methodto simulate the FSI. The research showed that the watertank could decrease the natural frequency and response ofthe shield building. Lu et al. [12] built a scaled elevatedtank to investigate the seismic response of shield buildingunder transient loadings. Moreover, numerical models wereestablished and the numerical results of acceleration and
HindawiScience and Technology of Nuclear InstallationsVolume 2018, Article ID 5094810, 13 pageshttps://doi.org/10.1155/2018/5094810
2 Science and Technology of Nuclear Installations
Natural convection air discharge
PCS gravity drain water tank
Water film evaporation
Outside cooling air intake
Steel containment vessel
Air baffle
Internal condensation and
natural recirculation
Figure 1: PCS of nuclear island building [20].
displacement were in good agreement with the experiment.Liu et al. [13] did the shaking table test of a scaled elevatedtank of passive containment cooling system water storagetank (PCCWST). An equivalent mechanical model was usedto predict the seismic forces of the PCCWST subjected tohorizontal ground excitation and the numerical results hada good agreement with the experiment.
In the research on dynamic characteristics of water tank,the main test method is using laser displacement sensorto measure the sloshing displacement of water; then thesloshing frequency could be calculated [14]. Aimed at slosh-ing damping ratio, the analytical solution or approximatesolution was derived only for containers with regular shape.The dynamic experiment was the commonly used method toobtain sloshing damping ratio, but the experimental resultslacked repeatability because of the nonlinear characteristic.
Sloshing frequency and damping ratio are the key param-eters of dynamic characteristic of the water tank. Moreover,they are also the key parameters to simplify the sloshinganalysis based on Housner model. Related scholars havedone some research on the sloshing frequency [15–17] andspecifications [18, 19] and also give the simplified calculationformulas on regular cylindrical tanks. But, for irregularannular cylindrical water tank, related specifications do notgive detailed introduction. Aimed at sloshing damping ratio,suggested values have been given for regular containers, but,for irregular containers, the research and verification are
deficient. As shown in Figure 1, PCS water tank is one kind ofirregular annular cylindrical water tank and the suggestion ofrelevant parameter may not be available in this case.
This study focuses on the interaction effects between thetank and water for the water tank of nuclear island building.As for the interaction effects between the water tank andnuclear island building, it will be studied separately. In thisstudy, a 1/16 scaled model was made for shaking table test.Pore water pressure sensors (PWPS) were arranged alongthe different height of tank walls and the cameras werearranged on the top of the tank, and the hydrodynamicpressure time-histories and attenuation data of wave heightwere collected. The sloshing frequencies and 1st sloshingdamping ratio can be obtained based on the test data. Bycomparing the experimental and numerical analysis results,the reasonableness of experimental method and the accuracyof numerical method are verified.
2. Shaking Table Test
2.1. Introduction of Model. Similarity relation of the experi-mental model was shown in Table 1. In this test, geometryL, elastic modulus 𝐸, and density 𝜌 were chosen as the basicsimilar constants. According to the size of shaking table, thematerials of model, the fluid characteristic, and the feasibilityof test, the similarity rules 𝑆𝑙, 𝑆𝐸, and 𝑆𝜌 were equal to 1/16,1/3, and 1. Then other similarity rules could be calculated.
Science and Technology of Nuclear Installations 3
Table 1: Similarity relation of the experimental model.
Physical quantity Similarity rule Similarity parameterGeometry 𝐿 𝑆𝑙 1/16Elastic modulus of concrete 𝐸𝐶 𝑆𝐸 1/3Density of concrete 𝜌𝐶 𝑆𝜌𝑐 1Bulk modulus of liquid 𝐺𝐿 𝑆𝐺 1Density of liquid 𝜌𝐿 𝑆𝜌𝑙 1Time of input motion 𝑡 𝑆𝑡 0.108Amplitude of input motion 𝑎 𝑆𝑎 5.333
(a)
Toughened glass
2110
Fixed part
Fixed bolts
Microconcrete
Model base
87533346280
60 60
307
318
55067
0
(b)
Figure 2: Introduction of model (unit : mm). (a) Experimental model. (b) The profile and geometry sizes.
To satisfy the rigid assumption of water tank, the tank wallsand bottom were made using microconcrete and the steelbars were replaced by galvanized iron wires. To test the waveheight, the roof of water tank was replaced by toughenedglass and connected to the water tank with fixed parts. Theexperimental model and the geometry sizes are shown inFigure 2.
To study the sloshing characteristic of liquid, the existingtest instruments are often laser displacement sensor or laservibration measuring instrument. Common laser displace-ment sensor might not satisfy the testing precision, but thehigh precision instruments or collection systems are veryexpensive. According to the theory of laser measurement,colored substance dissolved by organic solvent is used to
increase laser reflection. However, organic solvent like lac-quer thinner is easily volatile and may bring some risks.Moreover, this method could not catch the splash liquidduring the test [12] and the organic solvent may change thesloshing characteristic of liquid itself. Therefore, to recognizethe sloshing frequencies, PWPS shown in Figure 3 was usedto measure the hydrodynamic pressure in this paper.
To record the hydrodynamic pressure data, sixteen PWPSwere divided into two groups and they were arranged alongthe height of tank walls in 𝑥 cross section and 𝑦 cross sectionseparately. To record the attenuation data of wave height,rulers were arranged at the tank walls in 𝑥 cross section and𝑦 cross section. In addition, cameras were arranged on thetop of toughened glass. The PWPS can be placed in water
4 Science and Technology of Nuclear Installations
Table 2: Material parameters of experimental model.
Material parameters Microconcrete Toughened glass Galvanized iron wires WaterDensity (kg/m3) 2350 2560 7800 1000Young’s modulus (Pa) 1.05 × 1010 7.20 × 1010 2.06 × 1011 —Bulk modulus (Pa) — — — 2.30 × 109
Poisson’s ratio 0.17 0.20 0.30 —
Figure 3: Pore water pressure sensors (PWPS).
to record water pressures, the measurement ranges of PWPSare 30 kPa or 50 kPa, the strain output of full range is about500 × 10−6, and the precision of sensors is 0.3% F⋅S. Thearrangements of PWPS and cameras are shown in Figure 4.The material parameters of experimental model are listed inTable 2.
2.2. Experiment Process. According to the geometrical scaleof 1/16, the height of free water surface is 550mm. To rec-ognize the sloshing frequencies, single-direction sine waveswere used. The normalized sine wave is shown in Figure 5(a)and the peak ground acceleration is 0.05 g and 0.10 g. To verifythe reasonableness of numerical results, the three-directionacceleration time histories were used as inputs. Consideringthe space limit, one set of inputs is shown in this paper.The time history curves are shown in Figure 5(b) and thepeak ground acceleration of three-direction time histories is1.20 g, 0.80 g, and 0.60 g separately. Hydrodynamic pressureand attenuation data of wave height were recorded. Thenthe sloshing frequencies and 1st sloshing damping ratio wereobtained.
2.3. Data Analysis
2.3.1. Recognition of Sloshing Frequency. FFT is widely usedin the field of physics, acoustic, optics, structure dynamics,and signal processing. Based on FFT of data-signal, thesloshing frequency of liquid can be recognized throughhydrodynamic pressure. The typical application of FFT ischanging time histories into amplitude-frequency curves andthe basic equation is shown as follows:
𝐹 (𝜔) = ∫+∞−∞
𝑓 (𝑡) 𝑒−𝑖𝜔𝑡𝑑𝑡, (1)
where 𝑓(𝑡) is the time history of data-signal, 𝐹(𝜔) is thespectrum function of 𝑓(𝑡), and 𝜔 is the frequency.
In the experiment, the liquid would keep sloshing andthe wave height would gradually decay after the externalexcitation is ended. At that time, the hydrodynamic pressureand wave height only reflect the dynamic characteristic ofliquid in the tank without external excitation. As shown inFigure 6, hydrodynamic pressure in the free sloshing rangewas got and the pressure time curves could be changed intoamplitude-frequency curves by FFT. From Figure 6(c), thesloshing frequencies can be recognized.
Low sloshing frequencies play a control action in thedynamic analysis of liquid and seismic design of containers,especially the 1st sloshing frequency. So the first few sloshingfrequencies are needed to be recognized.The statistical resultsof first four sloshing frequencies recognized by hydrody-namic pressure data are listed in Table 3. Moreover, fortysamples are chosen and the errors between average value andtest value are shown in Figure 7.
As shown in Table 3, the coefficients of variation areall less than 5%. In Figure 7, the maximum errors of firstfour sloshing frequencies are 3.56%, 5.96%, 5.68%, and 2.91%separately. It proves that the test values have little discretenessand the results are acceptable.
2.3.2. Recognition of 1st Sloshing Damping Ratio. As oneimportant dynamic parameter, sloshing damping is mainlyfrom the friction between liquid and container. The value isrelated to four factors: viscous damping of inner wall, viscousdissipation of free fluid surface, viscous dissipation of liquidinside, and capillary of liquid inside. The sloshing dampingratio is often obtained through experiment because of thecomplexity of parameters. In this study, the 1st natural fre-quency of water tank is more than 50Hz and themodel couldbe regarded as rigid tank. The specifications propose thatthe basic sloshing damping ratio is 0.5% for normal tanks.However, it should be noted that, for higher viscosity fluidsand tanks with internal baffles, the damping ratio is higher.For the impulsive components, the basic damping ratio isgenerally assumed to be approximately 2%. For irregularcontainers, the specification does not give the suggestion.
Logarithmic decrement method is often used to calculatethe damping ratio of structure and the equation is shown:
𝛿 = ln𝜇𝑖𝜇𝑖+1 =
2𝜋𝜉√1 − 𝜉2 , (2)
where 𝛿 is the logarithmic decrement, 𝜇𝑖 and 𝜇𝑖+1 are theamplitudes of two adjacent periods, and 𝜉 is the dampingratio.
Science and Technology of Nuclear Installations 5
Cameras
Cameras
Y–section
X–section0 X
Y
(a)Y–section
Free fluid surface Free fluid surface
PWPS1
2
3
8
7
6
5 13
14
169
1510
11124
167
167
167
167
120
120
231 231 231231
50 50
X–section(b)
Figure 4: Layout of instruments. (a) Top view of model. (b) Layout of PWPS.
−1.5
−1.0
−0.5
0.0
0.5
1.0
1.5
Am
plitu
de
2 4 6 8 10 120Time (s)
(a)
X-directionY-directionZ-direction
t=6.142 s
1 2 3 4 5 6 7 8 9 100Time (s)
−1.5
−1.0
−0.5
0.0
0.5
1.0
1.5
Acce
lera
tion
(m/M
2)
(b)
Figure 5: Input time history curves for shaking table test. (a) Normalized sine wave. (b) Normalized seismic inputs in three directions.
On account of the small sloshing damping, the freevibration of liquid decays slowly. To satisfy the accuracyrequirement, the amplitudes of 𝑗 adjacent periods are usedto calculate the damping ratio. The damping ratio of smalldamping system can be calculated using the following equa-tion:
𝜉 ≈ 12𝜋𝑗 ln 𝜇𝑖𝜇𝑖+𝑗 . (3)
Logarithmic decrement method is one of the main meth-ods to calculate the damping ratio. Although (2) and (3) arederived by SDOF system, they are also applicable for MDOF[21]. The basic modal damping ratio (1st damping ratio) canbe obtained easily by free vibration test. The key to measure
higher modal damping ratio is to motivate free vibration ofthe corresponding mode. To FSI system, it is reasonable toconsider the structure and the fluid, respectively [21]. Theattenuation data of wave height are the parameters of sloshingwater and logarithmic decrement method can be used in thispaper.
As shown in Table 3, the 1st sloshing frequency is about0.5Hz. The period of sine wave input shown in Figure 5(a)is 2.0 s, so the 1st vibration mode can be motivated and the1st sloshing damping ratio can be calculated. Based on (3),The records from cameras are chosen to calculate 1st sloshingdamping ratio of water. The results are shown in Table 4 andFigure 8.
6 Science and Technology of Nuclear Installations
−2.0
−1.5
−1.0
−0.5
0.0
0.5
1.0
1.5H
ydro
dyna
mic
pre
ssur
e (KP
a)
10 20 30 40 50 60 70 80 900Time (s)
(a)
10 20 30 40 50 600Time (s)
−1.5
−1.0
−0.5
0.0
0.5
1.0
1.5
Hyd
rody
nam
ic p
ress
ure (
KPa)
(b)
−0.05
0.00
0.05
0.10
0.15
0.20
0.25
0.30
0.35
0.40
Am
plitu
de
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.00.0Frequency (Hz)
(c)
Figure 6: Data processing of hydrodynamic pressure records at No. 8 PWPS. (a) Time history curve. (b) Free sloshing range. (c) Amplitude-frequency curve.
Table 3: First four sloshing frequencies.
Modes Average value (AVG) (Hz) Standard deviation (SD) (Hz) Coefficient of variation (%)1 0.4938 0.0090 1.822 0.8404 0.0270 3.213 1.0015 0.0267 2.674 1.2188 0.0194 1.59
As shown in Table 4, The coefficient of variation is lessthan 5% and the discreteness is small. In Figure 8, the testvalues are almost betweenAVG− SD andAVG+SD. It provesthat the experimental results are reasonable and reliable. Theaverage value of 1st sloshing damping ratio is 0.5138% and itdoes not have much difference with the suggestion for theregular water tank in the specifications. Although the bottomof PCS water tank is inclined and the shape is irregular, 1stsloshing damping ratio changes little. The reasons may bethat the water tank is not irregular especially and the sloshingdamping ratio is too small. As a supplement, this conclusionmay not be available for other irregular water tanks.
3. Numerical Analysis and Discussion
3.1. Description of Numerical Model. In the field of FSI,ADINA software has strong solving capability. The equationsof the 𝜙 − 𝑢 formulation in this study are briefly introducedin this part.
As the special fluid element in ADINA [22], the potential-based fluid elements (PBFE) can be used for frequencyand time history analyses of structure [23, 24]. The basicassumptions are that the fluid is inviscid, compressible, orincompressible, with irrotational motion and small ampli-tude. There are two basic parameters in the formulation:
Science and Technology of Nuclear Installations 7
Maximum 3.56%
5 10 15 20 25 30 35 400Sample
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0Er
ror (
%)
(a)
Maximum 5.96%
0
1
2
3
4
5
6
7
Erro
r (%
)
5 10 15 20 25 30 35 400Sample
(b)
Maximum 5.68%
0
1
2
3
4
5
6
Erro
r (%
)
5 10 15 20 25 30 35 400Sample
(c)
Maximum 2.91%
5 10 15 20 25 30 35 400Sample
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
Erro
r (%
)
(d)
Figure 7: Statistics of errors between average value and test value. (a) 1st sloshing frequency. (b) 2nd sloshing frequency. (c) 3rd sloshingfrequency. (d) 4th sloshing frequency.
Table 4: Statistics of 1st sloshing damping ratio.
Average value (AVG) (%) Standard deviation (SD) (%) Coefficient of variation (%)0.5138 0.0212 4.13
velocity potential in fluid domain 𝜙 and displacement in soliddomain 𝑢.The velocity potential𝜙 satisfies thewave equation:
∇2𝜙 = 1𝐶2𝑤𝜕2𝜙𝜕2𝑡 , (4)
where ∇2 is the Laplace differential operator, 𝑡 is the timevariable, and 𝐶𝑤 is the wave velocity in fluid which is givenby
𝐶𝑤 = √𝜅𝑤𝜌𝑤 , (5)
where 𝜌𝑤 is water density and 𝜅𝑤 is the bulk modulus. Basedon the standard theories, the variational form of (4) can begot as
𝜌𝑤𝐶2𝑤 ∫𝑉𝑤𝜕2𝜙𝜕𝑡2 𝛿𝜙 𝑑𝑉 + 𝜌𝑤 ∫𝑆𝑤
∙u ⋅n𝛿𝜙 𝑑𝑆 + 𝜌𝑤 ∫𝑉𝑤
∇𝜙⋅ 𝛿∇𝜙𝑑𝑉 = 0,
(6)
where 𝑉𝑤 is the volume of water and 𝑆𝑤 is water boundarywhere normal velocity is prescribed. Under earthquake, thedynamic response of the water tank is coupled throughcompatibility of velocity potential and prescribed normal
8 Science and Technology of Nuclear Installations
Test valueAVG
AVG-SDAVG+SD
0.20
0.25
0.30
0.35
0.40
0.45
0.50
0.55
0.60
0.65
0.70
Dam
ping
ratio
(%)
5 10 15 20 25 30 35 400Sample
Figure 8: Statistics of 1st sloshing damping ratio.
velocity at the fluid-structure interface. The system dynamicequations of the tank filled with water can be obtained [25]:
[M𝑠𝑠 00 −M𝑤𝑤
][UΦ
] + [C𝑠𝑠 C𝑠𝑤C𝑤𝑠 0 ][
UΦ
]
+ [K𝑠𝑠 00 −K𝑤𝑤
][UΦ] = [−M𝑠𝑠1��𝑔 (𝑡)−C𝑤𝑠1��𝑔 (𝑡)] .
(7)
In addition
M𝑠𝑠 = 𝜌𝑠 ∫𝑉𝑠
N𝑇𝑠 N𝑠𝑑𝑉,M𝑤𝑤 = 𝜌𝑤𝐶2𝑤 ∫𝑉𝑤 N𝑇𝑤N𝑤𝑑𝑉,
K𝑠𝑠 = 𝜌𝑠 ∫𝑉𝑠
N𝑇𝑠 D𝑇𝑠 N𝑠𝑑𝑉,
K𝑤𝑤 = 𝜌𝑤 ∫𝑉𝑤
B𝑇𝑤B𝑤𝑑𝑉,C𝑠𝑤 = C𝑇𝑤𝑠 = −𝜌𝑤 ∫
𝑉𝑤
N𝑇𝑠 nN𝑤𝑑𝑆,C𝑠𝑠 = 𝛼M𝑠𝑠 + 𝛽K𝑠𝑠,
(8)
where N𝑠 and N𝑤 are standard isoparametric shape functionmatrices for shell and fluid elements, respectively. 𝜌𝑠 and 𝑉𝑠are the density and volume of the tank, D𝑠 is the elasticmatrix of shell elements, M𝑠𝑠 and K𝑠𝑠 are the mass andstiffness matrices for the tank, and M𝑤𝑤 and K𝑤𝑤 are themass and stiffness matrices for water. 1 is the column vectorwhich has the same dimension of nodal relative displacementU, C𝑤𝑠 and C𝑠𝑤 account for FSI between water and tank,and C𝑠𝑠 is the Rayleigh damping matrix for structure, inwhich 𝛼 and 𝛽 are the Rayleigh damping coefficients. As oneclassical damping matrix, Rayleigh damping matrix can be
used for common structures whose components have similardamping mechanism. The damping coefficients 𝛼, 𝛽 and thematrix B𝑤 in (5) are given by
𝛼 = 2𝜁𝜔𝑖𝜔𝑗𝜔𝑖 + 𝜔𝑗 ,𝛽 = 2𝜁𝜔𝑖 + 𝜔𝑗
B𝑤 = [[[[[
𝜕𝑁(1)𝑤𝜕𝑥 𝜕𝑁(2)𝑤𝜕𝑥 ⋅ ⋅ ⋅ 𝜕𝑁(𝑛)𝑤𝜕𝑥𝜕𝑁(1)𝑤𝜕𝑦 𝜕𝑁(2)𝑤𝜕𝑦 ⋅ ⋅ ⋅ 𝜕𝑁(𝑛)𝑤𝜕𝑦]]]]],
(9)
where 𝜁 is the damping ratio of structure, 𝜔𝑖 and 𝜔𝑗 arethe frequencies of structure, and 𝑛 is the number of nodesper fluid element. The chosen frequencies 𝜔𝑖 and 𝜔𝑗 shouldcover the frequency bands which are concerned in thestructural analysis. Moreover, the frequency bands should beconsidered by the dynamic characteristics of structure andthe external loads.
The experimental model is established and analyzed byADINA software. Solid finite elements are used to simulatethe model base and the water tank, and shell finite elementsare used to simulate the toughened glass.The software imple-ments the 𝜙 − 𝑢 described previously and the hydrodynamicpressures can be coupled to the vibration of solid elements byusing PBFE. So PBFE are used to simulate water in the tank.Thematerial parameters are the samewith experiment shownin Table 1. The numerical model is shown in Figure 9 and thesize of mesh is about 20–30mm.
3.2. Modal Analysis and Comparison. Considering the sym-metry of structure, the repeated modes are ignored. Thefirst four sloshing frequencies and the sloshing modes areshown in Figure 10. The frequencies are compared with theexperimental results and the errors are listed in Table 5. Theerrors of 1st, 2nd, and 4th sloshing frequencies are all lessthan 1%. Although the error of 3rd sloshing frequency islarger than other three, 6.15% error is acceptable.Through thecomparison, the reasonableness of numerical analysis and theaccuracy of experimental results are verified.
3.3. Time History Analysis and Comparison. In this part, thereasonableness of numerical analysis is verified in time his-tory analysis. The three-direction acceleration time historiesare used as inputs at the foundation of model and the timehistory curves are shown in Figure 5(b). The durations ofinputs are 6.142 s and the duration of strong motion is about3.50 s. Considering the free sloshing of water, the calculationtime is extended to 10 s.
Under the three-direction seismic loadings, the water isrotating along the walls of tank. The numerical results ofvertical sloshing displacement are shown in Figure 11. It canbe seen that the maximum vertical displacement appears notonly in 𝑥-axis or 𝑦-axis but also in other directions shownin Figure 11(a). The reason is that the rotating phenomenonof liquid surface often appears under seismic loadings and
Science and Technology of Nuclear Installations 9
(a)
Toughened glass
WaterMicroconcrete
(b)
Figure 9: Numerical model of water tank. (a) 3-D view. (b) Cross section.
(a) (b) (c) (d)
Figure 10: First four sloshing modes. (a) 1st sloshing frequency 0.4926Hz. (b) 2nd sloshing frequency 0.8399Hz. (c) 3rd sloshing frequency1.0631Hz. (d) 4th sloshing frequency 1.2085Hz.
(a) (b)
(c) (d)
Figure 11: Numerical results of vertical sloshing displacement. (a) Vertical sloshing displacement at 6.142 s. (b) Vertical sloshing displacementat 8.000 s. (c) Vertical sloshing displacement at 9.000 s. (d) Vertical sloshing displacement at 10.000 s.
10 Science and Technology of Nuclear Installations
Table 5: First four sloshing frequencies.
Sloshing modes Average value (Hz) Numerical analysis (Hz) Errors (%)1 0.4938 0.4926 −0.242 0.8404 0.8399 −0.063 1.0015 1.0631 +6.154 1.2188 1.2085 −0.85
0 1 2 3 4 5 6 7 8 9 10−0.15
−0.10
−0.05
0.00
0.05
0.10
0.15
Wav
e hei
ght (
m)
Time (s)
(a)
0 1 2 3 4 5 6 7 8 9 10−0.15
−0.10
−0.05
0.00
0.05
0.10
0.15
Wav
e hei
ght (
m)
Time (s)
(b)
Figure 12: The wave height under three-direction seismic loadings. (a) Inner wall-X section. (b) Outer wall-X section.
Free fluid surface
Centroid
233
219
217
550
309
462 80
Figure 13: The location of centroid of fluid (unit: mm).
the rotation direction is random. This is a typical bifurcationphenomenon of liquid in three-dimensional space and theoccurrence condition is related to external excitation and theviscosity of liquid [26].
The wave height time histories at the inner wall and theouter wall in 𝑥 cross section are shown in Figure 12. It can beseen that the vertical displacement of fluid surface at the innerwall is larger than that at the outer wall. After the seismicloadings, the sloshing of water is continuous and attenuatedconstantly.
It is known that the sloshing wave height is related tomany factors such as the density of liquid, the depth of liquid,and the shape of tank.The liquid properties are determined inthis paper, so the depth of liquid and the shape of tank mayinfluence the wave height. As shown in Figure 13, the cross
section of water tank is irregular. The liquid depth near theinner wall is about forty percent of the liquid depth near theouter wall and the centroid of liquid is closer to the outer wall.So the sloshing near the inner wall is more obvious than outerwall.
Under seismic loadings, the liquid in the containers willslosh and impact the walls of tank to affect the structuralresponse. The hydrodynamic pressure occurs because of theliquid motion and it may influence the structural intensityof water tank. The stronger the influence is, the higher thehydrodynamic pressure is and the larger the variation ofwave elevation is. The structural response of water tank willdirectly affect the response of the nuclear island building.So the hydrodynamic pressure should be considered in thedynamic analysis of water tank. The hydrodynamic pressureresults of numerical model are compared with those of theexperiment. Four reference points at the outer wall, innerwall, and bottom are chosen for comparison and the resultsare shown in Figure 14. The locations of PWPS are shown inFigure 4.
Figure 14(a) shows the hydrodynamic pressure timehistory of No. 8 PWPS. The shapes of two curves are ingood agreement generally. At the duration of seismic loadings(0–6.142 s), the curve of simulation has the smaller peaks thanexperimental one. In the stage of free sloshing, the peaks oftwo curves are close. But the corresponding times of peaksare not the same and have some deviations.
Figure 14(b) shows the hydrodynamic pressure timehistory of No. 9 PWPS. The simulation data agree well withthe experimental results in the shape of curve and the peaks.However, the experimental results are larger obviously atcertain time points.
Science and Technology of Nuclear Installations 11
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Figure 14: The hydrodynamic pressure under three-direction seismic loadings. (a) No. 8 PWPS. (b) No. 9 PWPS. (c) No. 10 PWPS. (d) No.12 PWPS.
Figure 14(c) shows the hydrodynamic pressure timehistory of No. 10 PWPS. The two curves do not have goodagreement, especially after the strong motion. But the peaksof two curves are close in the first 3 s.
Figure 14(d) shows the hydrodynamic pressure timehistory of No. 12 PWPS. The trends of two curves are similarto Figure 14(a).The curve of simulation has the smaller peaksin the duration of strong motion. Moreover, the peaks of twocurves are close after 3.5 s.
The four PWPS are located at outer wall, inner wall,the bottom, and the junction of wall and bottom separately.So the comparison results can verify the reasonableness ofnumerical analysis. The simulation data in Figures 14(a),14(b), and 14(d) agree with the experimental results ingeneral. No. 8 and No. 9 PWPS are close to the free liquidsurface, and No. 12 PWPS is at the middle of inclined bottom.So the sloshing response of the three reference points issimple and the curves agree well. But it is also found that the
simulation data of No. 10 PWPS fit poorly with experimentalresults.
It is well known that centroid vibration is the mainsource of sloshing force and moment. The centroid of liquidin the tank is shown in Figure 13. It can be seen that thelocation of centroid in vertical direction is very close to No.10 PWPS. The centroid moves near the initial position whenthe external excitation is applied, especially in the horizontaldirection. Moreover, No. 10 PWPS is at the junction of walland bottom. These factors may make the sloshing responsecomplicated at No. 10 PWPS. The numerical analysis couldnot simulate the complex sloshing well during the wholeprocess, but the peak and the trough of two curves do nothave too much difference in Figure 14(c).
In general, the accuracy of the formulation of PBFE isacceptable. It can be used to simulate the seismic response ofnuclear island building considering the FSI effect and studyon the influence of FSI on the seismic response.
12 Science and Technology of Nuclear Installations
4. Conclusion
A 1/16 scaled model was designed and the shaking tabletest was done in this study. PWPS and cameras were usedto record the time histories of hydrodynamic pressure andthe attenuation data of wave height. Based on the test data,the sloshing frequencies were recognized by FFT of hydro-dynamic pressure time histories and 1st sloshing dampingratio was calculated using logarithmic decrement method. Anumerical model of experimental water tank was establishedby ADINA software. Then modal analysis and time historyanalysis were done and the numerical results were comparedwith experimental data. The following conclusions could begot. They can be used to analyze the FSI of nuclear islandbuilding and simplify the sloshing analysis.(1)The measuring method of the water responses men-tioned in this paper can be used to recognize sloshingfrequencies. Comparing with the numerical analysis, theresult is acceptable.(2) 1st sloshing damping ratio of PCS water tank is0.5138% and the suggestion in the specification can be usedfor this irregular annular cylindrical water tank. But morestudies will be done to verify whether this conclusion issuitable for other shape tanks.(3)The formulation of PBFE is suitable formodal analysisand time history analysis, and the accuracy of numericalresults is acceptable.
Indeed, this paper focuses on the experimental model ofPCS water tank and the verification of numerical method.For the real nuclear island building, water tank and FSI effectmay influence the seismic response, floor response spectra,and the bearing capacity of the structure. Thus more studiesshould be done aimed at the seismic response of the wholenuclear island building.
Conflicts of Interest
There are no conflicts of interest related to this paper.
Acknowledgments
This research is supported by the National Natural ScienceFoundation of China (51738001, 51421005).Thanks are due tothe 19th International Conference on Structural Engineering,Vibration and Aerospace Engineering.
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